Up to 450 000 non-coding RNAs (ncRNAs) have been predicted to be transcribed from the human genome. However, it still has to be elucidated which of these transcripts represent functional ncRNAs. Since all functional ncRNAs in Eukarya form ribonucleo-protein particles (RNPs), we generated specialized cDNA libraries from size-fractionated RNPs and validated the presence of selected ncRNAs within RNPs by glycerol gradient centrifugation. As a proof of concept, we applied the RNP method to human Hela cells or total mouse brain, and subjected cDNA libraries, generated from the two model systems, to deep-sequencing. Bioinformatical analysis of cDNA sequences revealed several hundred ncRNP candidates. Thereby, ncRNAs candidates were mainly located in intergenic as well as intronic regions of the genome, with a significant overrepresentation of intron-derived ncRNA sequences. Additionally, a number of ncRNAs mapped to repetitive sequences. Thus, our RNP approach provides an efficient way to identify new functional small ncRNA candidates, involved in RNP formation

Alexander Hüttenhofer

Altschul

Amaral

Andrea Tanzer

Aravin

Bachellerie

Bartel

Birney

Brosius

Camblong

Carninci

Cavaille

Cheng

Cullen

Dignam

Eddy

Ender

Faghihi

Friedlander

Gardner

Gotoh

Gruber

Hertel

Hoffmann

Hubbard

Huttenhofer

Ivo L. Hofacker

Jochl

Juhling

Kapranov

Katrin Perfler

Kawaji

Kuhn

Lagos-Quintana

Lung

Madej

Marek Zywicki

Margulies

Mathieu Rederstorff

Mattick

Melanie Lukasser

Mercer

Mituyama

Mrazek

Muddashetty

Nawrocki

Ploner

Quentin

Reichow

Ryckelynck

Scheele

Sittka

Sleutels

Smalheiser

Stamm

Stephan H. Bernhart

Thompson

Umbach

Venter

Verma

Wagner

Washietl

Willingham

Wittig

Yamasaki

Nucleic Acids Research

English

PubMed

Up to 450,000 non-coding RNAs (ncRNAs) have been predicted to be transcribed from the human genome. However, it still has to be elucidated which of these transcripts represent functional ncRNAs. Since all functional ncRNAs in Eukarya form ribonucleo-protein particles (RNPs), we generated specialized cDNA libraries from size-fractionated RNPs and validated the presence of selected ncRNAs within RNPs by glycerol gradient centrifugation. As a proof of concept, we applied the RNP method to human Hela cells or total mouse brain, and subjected cDNA libraries, generated from the two model systems, to deep-sequencing. Bioinformatical analysis of cDNA sequences revealed several hundred ncRNP candidates. Thereby, ncRNAs candidates were mainly located in intergenic as well as intronic regions of the genome, with a significant overrepresentation of intron-derived ncRNA sequences. Additionally, a number of ncRNAs mapped to repetitive sequences. Thus, our RNP approach provides an efficient way to identify new functional small ncRNA candidates, involved in RNP formation

Rederstorff, Mathieu (Medizinische Universität Innsbruck)

Bernhart, Stephan (Department of Theoretical Chemistry, Faculty of Chemistry, University of Vienna)

Tanzer, Andrea (Department of Theoretical Chemistry, Faculty of Chemistry, University of Vienna)

Zywicki, Marek (Medizinische Universität Innsbruck)

Perfler, Katrin (Medizinische Universität Innsbruck)

Lukasser, Melanie (Medizinische Universität Innsbruck)

Hofacker, Ivo (Department of Theoretical Chemistry, Faculty of Chemistry, University of Vienna)

Hüttenhofer, Alexander (Medizinische Universität Innsbruck)

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RNPomics: defining the ncRNA transcriptome by cDNA library generation from ribonucleo-protein particles.

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RNPomics: Defining the ncRNA transcriptome by cDNA library generation from ribonucleo-protein particles

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RNPomics: Defining the ncRNA transcriptome by cDNA library generation from ribonucleo-protein particles

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